Lens barrel

ABSTRACT

A lens barrel is provided that includes an optical system, a housing, a cover member, an electronic part, a flexible substrate. The optical system is configured to form an optical image of a subject. The housing supports the optical system in an interior. The cover member supports the housing in a state of covering an opening of the housing. The electronic part is provided in the interior of the housing. The flexible substrate is electrically connected to the electronic part. The flexible substrate has a connection terminal. The cover member has a through-hole formed in a specific direction. The connection terminal is positioned on inside of the through-hole when viewed in the specific direction.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to Japanese Patent Application No.2010-163017 filed on Jul. 20, 2010 and Japanese Patent Application No.2011-155643 filed on Jul. 14, 2011. The entire disclosure of JapanesePatent Application No. 2010-163017 and Japanese Patent Application No.2011-155643 is hereby incorporated herein by reference.

BACKGROUND

1. Technical Field

The technology disclosed herein relates to a lens barrel equipped with aflexible substrate for connecting an electronic part inside the housingto an external member.

2. Description of the Related Art

There was known in the past a lens barrel equipped with a flexiblesubstrate for connecting an electronic part inside the housing to anexternal member.

Japanese Laid-Open Patent Application 2004-163748 discloses aconstitution in which a flexible substrate is passed through a holeprovided to a mounting component.

SUMMARY

The work entailed by threading the flexible substrate through the holeis troublesome and results in diminished work efficiency.

The technology disclosed herein was conceived in light of the aboveproblem, and it is an object thereof to provide a lens barrel with whichan electrical connection between an electronic part inside the housingand an external member can be easily made.

The stated object can be accomplished by the following lens barrel. Thelens barrel includes an optical system, a housing, a cover member, anelectronic part, a flexible substrate. The optical system is configuredto form an optical image of a subject. The housing supports the opticalsystem in an interior. The cover member supports the housing in a stateof covering an opening of the housing. The electronic part is providedin the interior of the housing. The flexible substrate is electricallyconnected to the electronic part. The flexible substrate has aconnection terminal. The cover member has a through-hole formed in aspecific direction. The connection terminal is positioned on inside ofthe through-hole when viewed in the specific direction.

The technology disclosed herein provides a lens barrel with which anelectrical connection between the electronic part inside the housing andan external member can be easily made.

BRIEF DESCRIPTION OF THE DRAWINGS

Referring now to the attached drawings which form a part of thisoriginal disclosure:

FIG. 1 is an oblique view of a lens barrel as seen from the front;

FIG. 2 is an oblique view of a lens barrel as seen from the rear;

FIG. 3 is an exploded oblique view of a lens barrel;

FIG. 4 is an oblique view of the configuration of a monitor unit;

FIG. 5 is an oblique view of a third movement frame as seen from thefront;

FIG. 6 is an oblique view of a third movement frame as seen from therear;

FIG. 7 is an oblique view of a fixed frame as seen from the rear;

FIG. 8 is a detail view of a portion of the fixed frame as seen in thedirection of the arrow P in FIG. 7;

FIG. 9 is an oblique view of a base member as seen from the front;

FIG. 10 is an oblique view of a base member as seen from the rear;

FIG. 11 is an oblique view illustrating a step of attaching a thirdmovement frame to a fixed frame;

FIG. 12 is an oblique view illustrating a step of engaging an FPC withan engagement component;

FIG. 13 is an oblique view illustrating a step of attaching a fourthmovement frame to a fixed frame;

FIG. 14 is an oblique view illustrating a step of attaching a monitorunit to a fixed frame;

FIG. 15 is an oblique view illustrating a step of attaching a monitorunit to a fixed frame;

FIG. 16 is an oblique view illustrating a step of attaching a flexiblesubstrate to first and second support bosses;

FIG. 17 is an oblique view illustrating a step of attaching a fixedframe to a rotary barrel;

FIG. 18 is an oblique view illustrating a step of attaching a basemember to a fixed frame;

FIG. 19 is an oblique view illustrating a step of attaching a basemember to a fixed frame;

FIG. 20 is a cross section of an assembly;

FIG. 21 is an oblique view illustrating a step of connecting an FPC to abase substrate;

FIG. 22 is a cross section of an assembly;

FIG. 23 is an oblique view illustrating a step of connecting a flexiblesubstrate to a base substrate;

FIG. 24 is a plan view of a state in which a base substrate has beenremoved from the assembly shown in FIG. 23;

FIG. 25 is an oblique view illustrating a step of attaching a firstmovement frame and a second movement frame to a fixed frame;

FIG. 26 is a cross section of a lens barrel in a telescoped state; and

FIG. 27 is an oblique view of another configuration of a through-hole127.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Selected embodiments will now be explained with reference to thedrawings. It will be apparent to those skilled in the art from thisdisclosure that the following descriptions of the embodiments areprovided for illustration only and not for the purpose of limiting theinvention as defined by the appended claims and their equivalents.

Simplified Configuration of Lens Barrel 100

The simplified configuration of the lens barrel 100 pertaining to anembodiment will be described through reference to the drawings. FIG. 1is an oblique view of the lens barrel 100 as seen from the front. FIG. 2is an oblique view of the lens barrel 100 as seen from the rear. FIG. 3is an exploded oblique view of the lens barrel 100.

In this embodiment, “front” and “rear” are terms based on a camera(including a camera body and a lens barrel) that is facing a subject,with the subject side being referred to as the “front” and the oppositeside from the subject the “rear.”

As shown in FIGS. 1 to 3, the lens barrel 100 comprises an opticalsystem L, a lens housing 110, a base member 120, an imaging element unit130, and a monitor unit 140. The lens barrel 100 is a part of a camera(including an interchangeable type), and is mounted to a camera bodythat is not shown.

Optical System L

The optical system L forms an optical image of a subject on an imagingelement 132 shown in FIG. 3. The optical system L is supported in theinterior of the lens housing 110. As shown in FIG. 3, the optical systemL has a first lens group LG1, a second lens group LG2, a third lensgroup LG3, and a fourth lens group LG4.

Lens Housing 110

The lens housing 110 supports the optical system L in its interior. Thelens housing 110 has a cylindrical external shape. As shown in FIG. 1, afront side opening of the lens housing 110 is covered by the opticalsystem L, and as shown in FIG. 2, a rear side opening of the lenshousing 110 is covered by the base member 120. As shown in FIG. 3, thelens housing 110 has a first movement frame 111, a second movement frame112, a third movement frame 113, a fourth movement frame 114, a fixedframe 115, and a rotary barrel 116.

The first movement frame 111 is a cylindrical member that holds otherparts constituting the lens housing 110. The first movement frame 111supports the first lens group LG1.

The second movement frame 112 is held in the interior of the fixed frame115. The second movement frame 112 supports the second lens group LG2.

The third movement frame 113 is held to the rear of the second movementframe 112 in the interior of the fixed frame 115. The third movementframe 113 supports the third lens group LG3. The configuration of thethird movement frame 113 will be described in detail below.

The fourth movement frame 114 is held to the rear of the third movementframe 113 in the interior of the fixed frame 115. The fourth movementframe 114 supports the fourth lens group LG4.

The fixed frame 115 is a cylindrical member that holds the secondmovement frame 112, the third movement frame 113, and the fourthmovement frame 114. The fixed frame 115 supports the second movementframe 112, the third movement frame 113, and the fourth movement frame114 so that they can move in the optical axis direction, and so thatthey do not rotate around the optical axis. The configuration of thefixed frame 115 will be described in detail below.

The rotary barrel 116 is a cylindrical member that holds the fixed frame115. The rotary barrel 116 is able to rotate around the optical axis.The rotary barrel 116 has a plurality of cam grooves formed in its outerperipheral face. Cam followers of the first movement frame 111, thesecond movement frame 112, and the third movement frame 113 are engagedin these cam grooves, and the cam followers move through the respectivecam grooves. Consequently, the first movement frame 111, the secondmovement frame 112, and the third movement frame 113 are each driven inthe optical axis direction.

Base Member 120

The base member 120 supports the rear end of the lens housing 110. Asshown in FIG. 3, the base member 120 has a cover main body 121, a basesubstrate 122, and a DC motor 123.

The cover main body 121 is cup-shaped externally. The cover main body121 is screwed down in a state of being fitted to the rear end of thelens housing 110.

The base substrate 122 is a flexible substrate that has the flexibility.Wiring is formed on inside and outside of the base substrate 122. Thebase substrate 122 is disposed on the rear side of the cover main body121 (that is, the opposite side from the side on which the lens housing110 is supported). The base substrate 122 is electrically connected to aflexible substrate 142 of the monitor unit 140 shown in FIG. 3, and to acontroller of the camera body (not shown). The base substrate 122transmits the electrical signals outputted by the camera body controllerto the flexible substrate 142.

The DC motor 123 is fixed to the outer periphery of the cover main body121. The DC motor 123 rotationally drives the rotary barrel 116. The DCmotor 123 is an example of an actuator. A DC motor, a stepping motor, anultrasonic motor featuring a piezoelectric element, or the like can beused as this actuator, for example.

The configuration of the base member 120 will now be described indetail.

Imaging Element Unit 130

The imaging element unit 130 is disposed on the rear side of the basemember 120. As shown in FIG. 3, the imaging element unit 130 has asupport plate 131 and the imaging element 132.

The support plate 131 supports the imaging element 132. The supportplate 131 is fixed to the rear face of the base member 120.

The imaging element 132 produces image data by capturing the opticalimage of a subject that is formed by the optical system L. The imagingelement 132 can be a CMOS image sensor, a CCD image sensor, or the like,for example.

Monitor Unit 140

The monitor unit 140 is fixed to the side face of the fixed frame 115 bya pair of screws 140 a. As shown in FIG. 3, the monitor unit 140 has astepping motor 141 and the flexible substrate 142.

The stepping motor 141 drives the fourth movement frame 114 in theoptical axis direction. More specifically, the fourth movement frame 114engaged with the lead screw (not shown) of the stepping motor 141 isdriven forward and backward according to the rotation of the lead screw.The monitor unit 140 is an example of an actuator. A DC motor, astepping motor, an ultrasonic motor featuring a piezoelectric element,or the like can be used as this actuator, for example.

The flexible substrate 142 is a resin substrate having wiring formed onits inner and outer surfaces. The flexible substrate 142 is electricallyconnected to the base substrate 122 and the stepping motor 141, as willbe discussed below. The flexible substrate 142 transmits electricalsignals inputted from the base substrate 122 to the stepping motor 141.

Here, FIG. 4 is an oblique view of the configuration of the monitor unit140. As shown in FIG. 4, the flexible substrate 142 is made up of aconnection component 142 a and a communicating component 142 b.

The connection component 142 a is formed as a thin sheet. The connectioncomponent 142 a constitutes the rear end of the flexible substrate 142,and sticks out rearward from the rear end of the stepping motor 141. Theconnection component 142 a has a connection face F, four connectionterminals a first fitting hole S1, and a second fitting hole S2. Theconnection face F is one main face of the connection component 142 a.The four connection terminals G are made up of solder, and are disposedon the connection face F. The first fitting hole S1 and the secondfitting hole S2 each pass through the connection component 142 a.

The communicating component 142 b is pliant and is narrower than theconnection component 142 a. The communicating component 142 b pivotablysupports the connection component 142 a. The communicating component 142b allows the connection component 142 a to communicate with the steppingmotor 141, and electrically connects the connection component 142 a andthe stepping motor 141.

The step of attaching the flexible substrate 142 to the fixed frame 115will be discussed below.

Detailed Configuration of Third Movement Frame 113

Next, the detailed configuration of the third movement frame 113 will bedescribed through reference to the drawings. FIG. 5 is an oblique viewof the third movement frame 113 as seen from the front. FIG. 6 is anoblique view of the third movement frame 113 as seen from the rear.

The third movement frame 113 has a frame main body 30, a supporting wall31, and flexible printed circuits (FPC) 32.

The frame main body 30 is cup-shaped externally. A fitting hole 30R forfitting the third lens group LG3 is formed on the inner bottom face 30 aof the frame main body 30.

As shown in FIG. 6, the supporting wall 31 is erected on the innerbottom face 30 a. The supporting wall 31 is disposed in the longitudinaldirection (that is, the optical axis direction). The supporting wall 31sticks out to the rear from the frame main body 30.

As shown in FIG. 5, the FPC 32 is made up of a reinforcing plate 32 a, afixed component 32 b, and a linking component 32 c. Wiring is formed oninside and on the surface of the reinforcing plate 32 a, the fixedcomponent 32 b, and the linking component 32 c.

The reinforcing plate 32 a is the free end located farther to the rearthan the supporting wall 31. The fixed component 32 b is fixed to theouter face of the supporting wall 31. The fixed component 32 b islocated closer to the frame main body 30 than the reinforcing plate 32a. The linking component 32 c is linked to the reinforcing plate 32 aand the fixed component 32 b. The linking component 32 c is more pliantthan the reinforcing plate 32 a, and includes a curved part 32S thatforms a shape that protrudes forward. The linking component 32 c gentlybends at the curved part 32S.

As shown in FIG. 6, the width va of the reinforcing plate 32 a isgreater than the width vb of the linking component 32 c. Consequently, apair of shoulders 32T that protrude to both sides of the linkingcomponent 32 c are formed at the front end of the reinforcing plate 32a.

Although not depicted, the third movement frame 113 has built into it ashutter mechanism, an image blur correction mechanism, and an aperturemechanism, and the actuators of the various mechanisms are electricallyconnected to the FPC 32. Also, as discussed below, the FPC 32 isconnected to the base substrate 122 and transmits the electrical signalsinputted from the base substrate 122 to the actuators of the variousmechanisms. This executes shutter operation, image blur correctionoperation, and aperture operation.

Detailed Configuration of Fixed Frame 115

Next, the detailed configuration of the fixed frame 115 will bedescribed through reference to the drawings. FIG. 7 is an oblique viewof the fixed frame 115 as seen from the rear.

The fixed frame 115 has a cylindrical component 50 and a flange 51 thatleads to the front end of the cylindrical component 50.

The cylindrical component 50 is formed in a cylindrical shape, and formsa space in its interior that accommodates the second movement frame 112,the third movement frame 113, and the fourth movement frame 114. Thecylindrical component 50 has a support base 50 a, a cut-out 50 b, and anengagement component 50 c.

The support base 50 a is formed at the rear end of the cylindricalcomponent 50. The support base 50 a is provided in order to support theconnection component 142 a part of the flexible substrate 142 had by themonitor unit 140. The support base 50 a has a first support boss T1 anda second support boss T2. The first and second support bosses T1 and T2are each formed in a cylindrical shape. The outside diameters of thefirst and second support bosses T1 and T2 respectively correspond to thefirst and second fitting holes S1 and S2 had by the connection component142 a of the flexible substrate 142.

In this embodiment, the first and second support bosses T1 and T2 aredisposed on inside of a through-hole 127 formed in the base member 120,as discussed below (see FIG. 24). The positional relation between thefirst and second support bosses T1 and T2 and the through-hole 127 willbe described in conjunction with the description of the step ofassembling the lens barrel 100.

The cut-out 50 b is provided adjacent to the support base 50 a. Thecommunicating component 142 b of the flexible substrate 142 had by themonitor unit 140 is inserted into the cut-out 50 b as discussed below.

The engagement component 50 c is formed at the rear end of thecylindrical component 50. FIG. 8 is a detail view of a portion of thefixed frame 115 as seen in the direction of the arrow P in FIG. 7. Asshown in FIG. 8, the engagement component 50 c is formed at the rear endface 50S of the cylindrical component 50 (that is, the end face that isopposite the base member 120).

The engagement component 50 c has a slit 500, a slit opening 510, andfirst to fourth protrusions 501 to 504. The engagement component 50 c isa cut-out which is formed at the rear end face 50S of the engagementcomponent 50 c. The slit opening 510 opens from the slit 500 into theinterior of the cylindrical component 50. The width wa of the slit 500is greater than the width wb of the slit opening 510. The width wa ofthe slit 500 is greater than the width va of the reinforcing plate 32 aof the FPC 32 (see FIG. 6), and the width wb of the slit opening 510 isgreater than the width vb of the linking component 32 c of the FPC 32(see FIG. 6). The first to fourth protrusions 501 to 504 are disposedinside the slit 500. The first protrusion 501 is disposed diagonallyacross from the second protrusion 502, and the third protrusion 503 isdisposed diagonally across from the fourth protrusion 504. The pair ofthe first and second protrusions 501 and 502, and the pair of the thirdand fourth protrusions 503 and 504 each hold one of the two shoulders32T of the FPC 32 in a bent state (indicated by the broken lines in FIG.8).

Detailed Configuration of Base Member 120

The detailed configuration of the base member 120 will now be describedthrough reference to the drawings. FIG. 9 is an oblique view of the basemember 120 as seen from the front. FIG. 10 is an oblique view of thebase member 120 as seen from the rear.

As shown in FIGS. 9 and 10, the base member 120 has a ring spring 124, aguide wall 125, a guide hole 126, and the through-hole 127 in additionto the above-mentioned cover main body 121, the base substrate 122, andthe DC motor 123.

As shown in FIGS. 9 and 10, the cover main body 121 as an inner bottomface 121A, an inner peripheral face 121B, an outer surface 121C, and anouter peripheral face 121D. The inner bottom face 121A is across fromthe rear end face of the lens housing 110. The inner peripheral face121B surrounds the outer periphery of the rear end of the lens housing110. The outer surface 121C is provided opposite the inner bottom face121A. The outer peripheral face 121D is provided opposite the innerperipheral face 121B.

The ring spring 124 is formed by a flat metal member. The ring spring124 is disposed along the inner peripheral face 121B on the inner bottomface 121A of the cover main body 121. The ring spring 124 is a biasingmember that biases the rotary barrel 116 forward and thereby reduceslooseness of the lens housing 110.

The guide wall 125 is erected on the inner bottom face 121A. The guidewall 125 is disposed in the longitudinal direction at a location closeto the inner peripheral face 121B. The function of the guide wall 125will be discussed below.

The guide hole 126 is formed in the optical axis direction. Morespecifically, the guide hole 126 passes through the cover main body 121from the inner bottom face 121A all the way to the outer surface 121C inthe optical axis direction. The guide hole 126 is formed between thering spring 124 and the guide wall 125 in a plan view of the innerbottom face 121A. Since the FPC 32 of the third movement frame 113 is tobe inserted into the guide hole 126, the guide hole 126 should have asize and shape that allow the insertion of the FPC 32.

The through-hole 127 is formed in the optical axis direction. Morespecifically, the through-hole 127 passes through the cover main body121 from the inner bottom face 121A all the way to the outer surface121C in the optical axis direction. The through-hole 127 is formed oninside of the ring spring 124 in a plan view of the inner bottom face121A. The planar shape of the through-hole 127 corresponds to theexternal shape of the connection component 142 a had by the flexiblesubstrate 142. However, the through-hole 127 need only have a size andshape that allow access to the four connection terminals G of theconnection component 142 a (see FIG. 4), and may be smaller than theexternal shape of the connection face F of the connection component 142a.

As shown in FIG. 10, the base substrate 122 here has a connectedcomponent 122 a, a cover 122 b, and a connector 122 c.

The connected component 122 a is formed as a thin sheet. The connectedcomponent 122 a is disposed in the through-hole 127, and substantiallycovers the through-hole 127. The connected component 122 a has fourconnected terminals J, a connection window K, a first fitting hole U1,and a second fitting hole U2. The four connected terminals J consist ofsolder, and are disposed around the connection window K. The connectionwindow K is a window that passes through the connected component 122 a.The connection window K should have a size and shape corresponding tothe four connection terminals G of the connection component 142 a had bythe flexible substrate 142 (see FIG. 4). The first fitting hole U1 andthe second fitting hole U2 each pass through the connected component 122a. The first and second fitting holes U1 and U2 are formed correspondingto the first and second fitting holes S1 and S2 of the connectioncomponent 142 a had by the flexible substrate 142.

The cover 122 b is a cover for blocking off the guide hole 126. Blockingoff the guide hole 126 with the cover 122 b helps prevent dirt and soforth from working its way into the interior of the lens housing 110.

The connector 122 c is disposed around the outer periphery of the basemember 120. The reinforcing plate 32 a of the FPC 32 is linked to theconnector 122 c.

Step of Assembling Lens Barrel 100

Next, the step of assembling the lens barrel 100 will be describedthrough reference to the drawings. The following will be describedbelow, in order: (1) attachment of the third movement frame 113 and thefourth movement frame 114 to the fixed frame 115, (2) attachment of themonitor unit 140 to the fixed frame 115, (3) attachment of the fixedframe 115 to the rotary barrel 116, (4) attachment of the base member120 to the fixed frame 115, (5) connection of the FPC 32 to the basesubstrate 122, (6) connection of the flexible substrate 142 to the basesubstrate 122, and (7) attachment of the first movement frame 111 andthe second movement frame 112 to the fixed frame 115.

(1) Attachment of Third Movement Frame 113 and Fourth Movement Frame 114to Fixed Frame 115

First, as shown in FIG. 11, the third movement frame 113 is insertedinto the interior of the fixed frame 115 from the rear of the fixedframe 115. Here, the position of the FPC 32 of the third movement frame113 is matched to the position of the engagement component 50 c of thefixed frame 115.

Next, as shown in FIG. 12, the reinforcing plate 32 a of the FPC 32 isinserted into the slit 500 of the engagement component 50 c, and thelinking component 32 c of the FPC 32 is pulled inside the fixed frame115 through the slit opening 510 of the engagement component 50 c. Here,the pair of shoulders 32T of the reinforcing plate 32 a are each held ina bent state by the first to fourth protrusions 501 to 504 on inside ofthe slit 500 (see FIG. 8).

Next, as shown in FIG. 13, the fourth movement frame 114 is insertedinto the interior of the fixed frame 115 from the rear of the fixedframe 115.

(2) Attachment of Monitor Unit 140 to Fixed Frame 115

Next, as shown in FIG. 14, the monitor unit 140 is fixed to the sideface of the fixed frame 115 with a pair of screws 140 a. Here, as shownin FIG. 15, the communicating component 142 b of the flexible substrate142 is inserted into the cut-out 50 b of the fixed frame 115, and theconnection component 142 a of the flexible substrate 142 is made toprotrude to the rear of the fixed frame 115.

Next, as shown in FIG. 16, the flexible substrate 142 is bent at thecommunicating component 142 b, and the first and second fitting holes S1and S2 of the connection component 142 a had by the flexible substrate142 are fitted into the first and second support bosses T1 and T2 had bythe support base 50 a of the fixed frame 115. Consequently, theconnection component 142 a of the flexible substrate 142 is supported bythe first and second support bosses T1 and T2 on the support base 50 a.

(3) Attachment of Fixed Frame 115 to Rotary Barrel 116

Next, as shown in FIG. 17, the fixed frame 115 is inserted into theinterior of the rotary barrel 116 from the front of the rotary barrel116. Here, the reinforcing plate 32 a of the third movement frame 113protrudes to the rear of the rotary barrel 116, and the connectioncomponent 142 a of the flexible substrate 142 is exposed from the rearend of the rotary barrel 116.

(4) Attachment of Base Member 120 to Fixed Frame 115

Next, as shown in FIG. 18, the base member 120 is fitted into the rotarybarrel 116 from the rear of the fixed frame 115. Here, the reinforcingplate 32 a of the third movement frame 113 is inserted into the guidehole 126 of the base member 120, and the connection component 142 a ofthe flexible substrate 142 is placed opposite the connected component122 a of the base substrate 122 had by the base member 120.

Next, as shown in FIG. 19, the base member 120 is fixed to the fixedframe 115 by a plurality of screws 120 a. This completes an assembly 110a. With the assembly 110 a, the reinforcing plate 32 a of the FPC 32protrudes from the guide hole 126, and the connection component 142 a ofthe flexible substrate 142 and the connected component 122 a of the basesubstrate 122 are opposite each other on inside of the through-hole 127.

FIG. 20 here is a cross section of an assembly 100 a. As shown in FIG.20, the FPC 32 is sandwiched between the third movement frame 113 andthe fixed frame 115 in an overall state of being bent in a protrudingshape toward the front. More specifically, the reinforcing plate 32 a isengaged with the engagement component 50 c of the fixed frame 115, andthe fixed component 32 b is fixed to the supporting wall 31 of the thirdmovement frame 113. The linking component 32 c is gently bent at thecurved part 32S formed between the inner wall of the fixed frame 115 andthe supporting wall 31 of the third movement frame 113. Also, thelinking component 32 c is sandwiched between the inner wall of the fixedframe 115 and the guide wall 125 of the base member 120 near thereinforcing plate 32 a.

(5) Connection of FPC 32 to Base Substrate 122

Next, as shown in FIG. 21, the reinforcing plate 32 a is pulled out ofthe guide hole 126 and inserted into the connector 122 c of the basesubstrate 122. Consequently, the FPC 32 is mechanically and electricallyconnected to the base substrate 122.

Next, the guide hole 126 of the base member 120 is covered by the cover122 b of the base substrate 122.

FIG. 22 here is a cross section of the assembly 100 a. As shown in FIG.22, even after the reinforcing plate 32 a has been pulled out of theguide hole 126, the linking component 32 c is gently bent at the curvedpart 32S′. The curved part 32S′ is positioned further to the rear thanthe curved part 32S (see FIG. 20), but is formed between the inner wallof the fixed frame 115 and the supporting wall 31 of the third movementframe 113, just as is the curved part 32S.

FIG. 22 corresponds to the telephoto zoom state of the completed lensbarrel 100.

(6) Connection of Flexible Substrate 142 to Base Substrate 122

Next, as shown in FIG. 23, the four connection terminals G had by theconnection component 142 a of the flexible substrate 142 are exposedthrough the connection window K of the connected component 122 a, andmatched to the positions of the four connected terminals J had by theconnected component 122 a. Consequently, the electrically connectedparts between the flexible substrate 142 and the base substrate 122(that is, the connection terminals G and the connected terminals J) arelocated on inside of the through-hole 127 when viewed in the opticalaxis direction. In this embodiment, “when viewed in the optical axisdirection” is defined as being the same as a plan view of the outersurface 121C.

Next, the connection terminals G are soldered to the connected terminalsJ. Consequently, the flexible substrate 142 is electrically andmechanically connected to the base substrate 122.

FIG. 24 here is a plan view of a state in which the base substrate 122has been removed from the assembly 100 a shown in FIG. 23. As shown inFIG. 24, the four connection terminals G are disposed on inside of thethrough-hole 127 when viewed in the optical axis direction. The firstand second support bosses T1 and T2 that support the connectioncomponent 142 a of the flexible substrate 142 are disposed on inside ofthe through-hole 127 when viewed in the optical axis direction. Also,substantially the entire connection face F of the connection component142 a is disposed on inside of the through-hole 127 when viewed in theoptical axis direction.

Also, as shown in FIG. 24, the through-hole 127 is formed on inside ofthe ring spring 124 in a plan view of the outer surface 121C.Accordingly, the connection component 142 a exposed on inside of thethrough-hole 127 is also disposed on inside of the ring spring 124.

Further, as shown in FIG. 24, the engagement component 50 c (morespecifically, the slit 500) is disposed on inside of the guide hole 126when viewed in the optical axis direction. The guide hole 126 is formedon inside of the ring spring 124 in a plan view of the outer surface121C, and the engagement component 50 c is disposed on inside of thering spring 124.

(7) Attachment of First Movement Frame 111 and Second Movement Frame 112to Fixed Frame 115

Next, the second movement frame 112 is inserted into the interior of thefixed frame 115 from the front of the assembly 100 a (see FIG. 3).

Next, the first movement frame 111 is fitted to the front end of therotary barrel 116 from the front of the assembly 100 a.

Next, the rotary barrel 116 is rotationally driven by the DC motor 123,which telescopes the first movement frame 111, the second movement frame112, and the third movement frame 113 as shown in FIG. 25.

After this, the imaging element unit 130 (not shown) is fixed to therear side of the base member 120, which completes the assembly of thelens barrel 100.

FIG. 26 here is a cross section of the lens barrel 100 in its telescopedstate. As shown in FIG. 26, even in the telescoped state, the linkingcomponent 32 c of the FPC 32 is gently bent at a curved part 32S″. Thecurved part 32S″ is located further to the rear than the curved part32S′ (see FIG. 22), but is formed between the inner wall of the fixedframe 115 and the supporting wall 31 of the third movement frame 113,just as is the curved part 32S′. Also, part of the linking component 32c is sandwiched between the inner wall of the fixed frame 115 and theguide wall 125 of the base member 120. Thus, the FPC 32 is gently bentonly once, and is not bent over itself or twisted.

Action and Effects

(1) With the lens barrel 100 pertaining to this embodiment, the flexiblesubstrate 142 has the four connection terminals G (an example of a“connection terminal”). The base member 120 (an example of a “covermember”) has the through-hole 127 (an example of a “through-hole”)formed in the optical axis direction (an example of a “specificdirection”). The four connection terminals G are located on inside ofthe through-hole 127 when viewed in the optical axis direction.

Therefore, the four connection terminals G can be easily accessed viathe through-hole 127, so the flexible substrate 142 and the basesubstrate 122 can be simply electrically connected without having topass the flexible substrate 142 through the through-hole 127 in the stepof assembling the lens barrel 100. As a result, work efficiency can beimproved in the step of assembling the lens barrel 100.

(2) The four connection terminals G are formed on the connectioncomponent 142 a (an example of “one end”) of the flexible substrate 142.The lens housing 110 has the first and second support bosses T1 and T2(an example of a “support component”) that support the connectioncomponent 142 a.

Therefore, since it is supported by the first and second support bossesT1 and T2, when the base member 120 is attached to the fixed frame 115,the end of the flexible substrate 142 is less apt to be erroneouslysandwiched between the base member 120 and the fixed frame 115 androtary barrel 116.

(3) The connected component 122 a of the base substrate 122substantially covers the through-hole 127. Therefore, this helps preventdirt and so forth from working its way into the interior of the lenshousing 110 through the through-hole 127.

(4) The base member 120 has the ring spring 124 disposed on the innerbottom face 121A (an example of an “opposing face”) that is opposite thelens housing 110. The through-hole 127 is formed on inside of the ringspring 124 in a plan view of the inner bottom face 121A.

Thus, the flexible substrate 142 is not sandwiched between the lenshousing 110 and the ring spring 124. Therefore, while the lens barrel100 is being used, the flexible substrate 142 is less apt to be damagedby friction between the lens housing 110 and the ring spring 124.

(5) Also, with the lens barrel 100 pertaining to this embodiment, thefixed frame 115 has the engagement component 50 c formed at the rear endface 50S that is opposite the base member 120. The base member 120 hasthe guide hole 126 into which the FPC 32 is inserted. The engagementcomponent 50 c is located on inside of the guide hole 126 when viewed inthe optical axis direction.

Therefore, the FPC 32 engaged in the engagement component 50 c can beeasily inserted into the guide hole 126, so the FPC 32 can be simplypulled out of the guide hole 126.

Also, since the base member 120 can be attached to the fixed frame 115in a state in which the FPC 32 is engaged with the engagement component50 c, the FPC 32 is less able to be erroneously sandwiched between thebase member 120 and the fixed frame 115 and rotary barrel 116.

(6) The engagement component 50 c is the slit 500 formed in the rear endface 50S.

Therefore, after the base member 120 has been attached to the fixedframe 115, the engagement of the FPC 32 by the engagement component 50 ccan be easily released.

(7) The engagement component 50 c has the first to fourth protrusions501 to 504 that protrude to the inside of the slit 500.

Therefore, when the reinforcing plate 32 a of the FPC 32 has beeninserted into the slit 500, the first to fourth protrusions 501 to 504hit the reinforcing plate 32 a, and the frictional force thus producedallows the reinforcing plate 32 a to be securely supported.

(8) The first protrusion 501 is disposed diagonally across from thesecond protrusion 502, and the third protrusion 503 is disposeddiagonally across from the fourth protrusion 504.

Therefore, the FPC 32 can be bent by the first and second protrusions501 and 502 and by the third and fourth protrusions 503 and 504.Accordingly, creasing of the FPC 32 is suppressed, so the FPC 32 can beinserted more accurately into the guide hole 126.

(9) The base member 120 has the guide wall 125 erected on the innerbottom face of the cover main body 121. The linking component 32 c ofthe FPC 32 is sandwiched between the inner wall of the fixed frame 115and the guide wall 125 near the reinforcing plate 32 a.

Therefore, whether the lens housing 110 is in its telescoped state or inits telephoto zoom state, the FPC 32 is not bent over itself or twisted.

Other Embodiments

The above embodiment was given as an example of an embodiment of thepresent invention. But the present invention is not limited by this.Other embodiments will therefore be compiled and described below. Nor isthe present invention limited to or by these other embodiments, and canbe applied to embodiments that have been suitably modified.

(1) The first and second support bosses T1 and T2 are an example of asupport component that supports the flexible substrate 142. This supportcomponent that supports the flexible substrate 142 may be any supportstructure, such as a magnet or tape that affixes the flexible substrate142, a slit that engages with the flexible substrate 142, or the like.

(2) The flexible substrate 142 may be connected to any electronic partincluded in the interior of the lens housing 110. For instance, it maybe connected to a motor or the like, or may be connected to a circuitboard.

(3) The through-hole 127 may pass through the cover main body 121 in theoptical axis direction, or may pass through the cover main body 121 insome other direction.

(4) The electrical connection between the flexible substrate 142 and thebase substrate 122 need not be connection by soldering, and may be anykind of connection such as connection using a connector, or the like.

(5) The optical system L may be one in which the optical axis is bent bya bending optical system such as a prism or a mirror. In this case, thelens housing 110 may be bent along the optical axis.

(6) The engagement component 50 c was said to have the slit 500 forinserting the FPC 32, but this is not the only option. The engagementcomponent 50 c may, for example, be any support structure such as amagnet or tape that affixes the FPC 32, a protrusion that is fitted intothe FPC 32, or the like. Also, the engagement component 50 c may beprovided to a member other than the fixed frame 115, such as the thirdmovement frame 113, the fourth movement frame 114, or the rotary barrel116.

(7) The FPC 32 was said to have the reinforcing plate 32 a, but this isnot the only option. The FPC 32 may have no reinforcing plate 32 a, andmay be made of a material that is highly pliant overall. Here again, theFPC 32 can be raised up toward the base member 120 by bending the FPC 32with the first to fourth protrusions 501 to 504 that protrude into theslit 500.

(8) The engagement component 50 c bent the FPC 32 with the first tofourth protrusions 501 to 504 that protruded into the slit 500, but thisis not the only option. For example, the FPC 32 may be bent by formingthe slit 500 itself in an arc shape.

(9) The FPC 32 was engaged with the engagement component 50 c by beinginserted into the slit 500, but this is not the only option. Theengagement component 50 c may be any support structure, such as a magnetor tape that affixes the FPC 32, a cut-out into which the side end ofthe FPC 32 is meshed, or the like.

(10) The flexible substrate 111 may be connected to any electronic partthat is included in the interior of the lens housing 110. For example,it may be connected to a detecting element, a motor, or the like, or maybe connected to a circuit board.

(11) The external shape of the lens housing 110 is not limited to beingcylindrical, and may be cuboid or some other shape. Also, the lenshousing 110 opened in the optical axis direction, but may instead openin a direction perpendicular to the optical axis.

(12) The second movement frame 112 was pliant, but need not be pliant.

(13) The flexible substrate 142 was attached to the fixed frame 115 thatwas fixed to the base member 120, but this is not the only option. Theflexible substrate 142 may be attached to a member that is capable ofrelative movement with respect to the base member 120. Examples of sucha member include the first movement frame 111, the second movement frame112, the third movement frame 113, the fourth movement frame 114, andthe rotary barrel 116.

(14) The four connection terminals G were disposed in the interior ofthe lens housing 110, and could be accessed via the through-hole 127,but this is not the only option.

For example, the connection terminals G may be disposed so that theyprotrude outside the lens housing 110 from the through-hole 127. Also,the connection component 142 a of the flexible substrate 142, theengagement component support base 50 a of the fixed frame 115, or thelike may also protrude from the through-hole 127. In this case, if thegap between the support base 50 a and the through-hole 127 is madesmaller, this will help prevent dirt or the like from working its wayinto the interior of the lens housing 110 through the through-hole 127.

However, it is preferable for the four connection terminals G to bedisposed in the interior of the lens housing 110 as in the aboveembodiment. This is because it is simpler to reduce the gap between theconnected component 122 a and the through-hole 127 and thereby preventdirt or the like from working its way into the interior of the lenshousing 110 through the through-hole 127.

(15) The through-hole 127 passed through the cover main body 121 fromthe inner bottom face 121A all the way to the outer surface 121C in theoptical axis direction, but this is not the only option. For instance,as shown in FIG. 27, the through-hole 127 may pass through the covermain body 121 from the outer peripheral face 121D to the innerperipheral face 121B. In this case, the through-hole 127 is formed in adirection that intersects (is perpendicular to) the optical axisdirection.

(16) The connection component 142 a including the four connectionterminals G constituted the rear end of the flexible substrate 142, butthis is not the only option. The position of the connection component142 a on the flexible substrate 142 can be changed as desired.

What is claimed is:
 1. A lens barrel, comprising: an optical systemconfigured to form an optical image of a subject; a housing supportingthe optical system in an interior thereof; a cover member supporting thehousing in a state of covering an opening of the housing; an electronicpart provided in the interior of the housing; and a flexible substrateelectrically connected to the electronic part, the flexible substratehaving a connection terminal, the cover member having a through-holeformed in a specific direction, and the connection terminal beingpositioned on inside of the through-hole when viewed in the specificdirection.
 2. The lens barrel according to claim 1, wherein theconnection terminal is formed at one end of the flexible substrate, andthe housing has a support component that supports the one end of theflexible substrate.
 3. The lens barrel according to claim 1, wherein theconnection terminal is formed on a connection face of the flexiblesubstrate, and the connection face is positioned on inside of thethrough-hole when viewed in the specific direction.
 4. The lens barrelaccording to claim 1, further comprising: a base substrate disposedopposite to the housing with the cover member in between as a reference,and the base substrate being electrically connected to the connectionterminal.
 5. The lens barrel according to claim 4, wherein the basesubstrate has a connected terminal that is electrically connected to theconnection terminal, and the connected terminal is positioned on insideof the through-hole when viewed in the specific direction.
 6. The lensbarrel according to claim 5, wherein the base substrate covers thethrough-hole.
 7. The lens barrel according to claim 4, wherein the basesubstrate is a pliant flexible substrate.
 8. The lens barrel accordingto claim 1, wherein the cover member is a base member that supports thehousing.
 9. The lens barrel according to claim 8, wherein the basemember supports an imaging element.
 10. The lens barrel according toclaim 1, wherein the cover member has a ring spring disposed on anopposing face that is opposite to the housing, and the through-hole isformed on inside of the ring spring when seen in plan view of theopposing face.